JP5841906B2 - Failure detection device, failure detection system, and failure detection method - Google Patents

Description

  The present invention relates to a failure detection device, a failure detection system, and a failure detection method for a bypass diode attached to a solar cell.

  In general, in a solar cell module that generates power using sunlight, a reverse voltage may be applied to the solar cell due to, for example, variations in characteristics, fluctuations in solar radiation intensity, and the like, and this reverse voltage increases. In such a case, there is a risk that the solar cell may generate heat and be damaged. Therefore, as a conventional solar cell module, there is known a module in which a bypass diode is connected in parallel to a solar cell and an excessive reverse voltage is prevented from being applied to the solar cell.

  In such a solar cell module, as described in Patent Document 1 below, for example, a failure detection device that detects an open mode (also referred to as an open mode) failure of a bypass diode has been developed. In the inspection apparatus described in Patent Document 1, the solar cell is shielded from light by the shielding plate, and the temperature of the light shielding portion of the solar cell is detected by the thermal paper integrated with the shielding plate. And when generation | occurrence | production of hot spot heat | fever (abnormal heat_generation | fever) is detected in the shielding part of a solar cell, it determines with the electric current not flowing into a bypass diode, and, thereby, determines with the bypass diode having an open mode failure.

  Patent Document 2 below discloses a technique for finding a failure of a bypass diode based on the electrical characteristics of a solar cell module. In detail, in this diagnostic method, a charged capacitor is connected to a measurement target part excluding the blocking diode of the solar cell string and discharged, and the voltage and current of the measurement target part are measured at the time of discharging. -Diagnose the failure of the measurement target part based on the change of the V characteristic.

JP 2001-024204 A JP 2011-66320 A

  However, in the diagnostic method according to Patent Document 1, it is necessary to shield the solar cell in order to detect an open mode failure of the bypass diode. However, since the solar cell is usually installed at a high place such as a roof, it is shielded from light. There is a problem that the work is complicated and not suitable for daily inspection from the viewpoint of safety and cost. In addition, when this technology is applied, it is difficult to determine whether or not the bypass diode has failed for the following reason. That is, even when the bypass diode does not have an open mode failure, when the solar cell is shielded from light, a certain amount of reverse voltage is applied to the solar cell, and heat generation of the solar cell may be observed. The degree of heat generation depends on the solar radiation intensity at that time, the light shielding state, the solar cell current density, the solar cell heat dissipation state, and the shunt resistance component of the solar cell. It is extremely difficult to distinguish between heat generation and heat generation due to a failure of the bypass diode. Therefore, there is a possibility that an open mode failure of the bypass diode cannot be accurately detected.

  Further, in the diagnostic method according to Patent Document 2, when there is no defect in the measurement target part, a large current corresponding to the voltage of the capacitor instantaneously flows to the measurement target part. It is not preferable also in terms of safety during measurement. Although it is conceivable to reduce the capacitance of the capacitor in order to reduce the large current at the measurement target part, in this case, since the measurement time of the IV characteristic cannot be made long, reliable measurement of the IV characteristic is possible. In some cases, the accuracy of failure diagnosis may be reduced.

  Therefore, the present invention has been made in view of such a problem, a failure detection device capable of reliably and easily detecting a failure of a bypass diode built in a solar cell module while ensuring safety, It is an object to provide a failure detection system and a failure detection method.

  In order to solve the above-described problem, a failure detection device according to one aspect of the present invention includes a solar cell that generates power using sunlight and at least one bypass diode connected in parallel to the solar cell, and is provided in a load. A failure detection device for detecting a failure of a bypass diode targeting at least one solar cell module in a disconnected state, and supplying a current having a specified current value from the negative electrode to the positive electrode of the solar cell module A voltage source that measures a potential difference between the negative electrode and the positive electrode of the solar cell module when current is supplied by the current source, and determines a failure of the bypass diode based on the potential difference measured by the voltage measurer A determination unit.

  Alternatively, a failure detection method according to another aspect of the present invention includes a solar cell that generates power using sunlight and at least one bypass diode connected in parallel to the solar cell, and is disconnected from the load. A failure detection method for detecting a failure of a bypass diode for at least one solar cell module in a state, wherein a current supply step of supplying a current of a specified current value from a negative electrode of the solar cell module to a positive electrode And a voltage measurement step for measuring a potential difference between the negative electrode and the positive electrode of the solar cell module during current supply by the current supply step, and a determination step for determining a failure of the bypass diode based on the potential difference measured by the voltage measurement step And comprising.

  According to such a failure detection device or failure detection method, a specified current value from the negative electrode to the positive electrode with respect to at least one solar cell module that includes at least one bypass diode and is in a disconnected state with respect to the load. The potential difference generated between the negative electrode and the positive electrode of the solar cell module at that time is measured, and a failure of the bypass diode is detected based on the potential difference. That is, if the bypass diode is normal, the potential difference is almost the same as the voltage drop value of the bypass diode, and if the bypass diode has an open mode failure, the parasitic resistance of the solar cell module (for example, the shunt resistance in the solar cell) ) Occurs, the potential difference becomes larger than the voltage drop value of the bypass diode. Therefore, according to the above-described failure detection apparatus or failure detection method, the presence or absence of a failure of the bypass diode can be determined with high accuracy by detecting the difference in the magnitude of the potential difference. In addition, by measuring the potential difference in the constant current state, there is little risk of flowing a large current through the solar cell module, and there is no need to scan the IV characteristics as in the failure detection method using a capacitor. Thereby, the failure of the bypass diode can be detected easily and reliably while ensuring the safety at the time of inspection.

  In the failure detection apparatus described above, the determination unit is measured in a state where a current having a first value that is larger than the short-circuit current value of the solar cell module is supplied to the solar cell module as a specified current value. It is preferable to detect a failure of the bypass diode when the potential difference is larger than the first threshold value. In this way, the failure of the bypass diode can be detected with a simple process and circuit configuration by comparing the measured potential difference with the threshold value.

  Further, the determination unit is linear based on a change in potential difference measured in a state where the first and second current values are supplied as the prescribed current values to the solar cell module. It is also preferable that a failure of the bypass diode is detected based on whether or not, and at least one of the first and second current values is larger than the short-circuit current value of the solar cell module. By adopting such a configuration, by determining whether the measured potential difference changes linearly, it is possible to determine whether the voltage drop is caused by the parasitic resistance of the solar cell module or the bypass diode. Can do. As a result, it is possible to realize more reliable failure detection in consideration of characteristic changes due to aging of the bypass diode.

  Furthermore, the determination unit is configured such that a potential difference measured in a state where a current having a first value that is larger than a short-circuit current value of the solar cell module is supplied as a specified current value to the solar cell module is It is also preferable to stop the supply of current to the solar cell module when it is larger than the threshold value of 1, or when the potential difference becomes equal to or greater than a second threshold value that is equal to or greater than the first threshold value. If such a determination unit is provided, it is possible to prevent a failure of the solar cell module caused by applying a high voltage to the solar cell module at the time of failure inspection. That is, if a constant current larger than the short-circuit current is passed through the solar cell module, a high voltage in the opposite direction to the voltage generated during power generation in the solar cell module may be generated, but the potential difference of the solar cell module is the first. Alternatively, the generation of such a high voltage can be prevented by stopping the supply of current when the second threshold value is reached.

  Further, the determination unit is based on a comparison result between a short circuit current value measured when the solar cell module is short-circuited or an open-circuit voltage measured when the solar cell module is opened and a specified value. It is also preferable to determine whether or not the module is generating power, and to start determining whether or not the bypass diode has failed when it is determined that the solar cell module is not generating power. By adopting such a configuration, the power generation state of the solar cell module can be determined by a simple determination method or a simple determination circuit.

  Alternatively, the failure detection system according to another aspect of the present invention includes a plurality of solar cells connected in series that generate power using sunlight and at least one bypass diode connected in parallel to the plurality of solar cells. Failure detection for detecting a failure of a bypass diode in a solar cell system including a solar cell string including a plurality of solar cell modules connected in series and a load device connected to the solar cell string A switching unit that switches a connection between a solar cell string and a load device to a disconnected state, and a solar cell string that is switched to a disconnected state by the switching unit as a detection target string. A current source that supplies a current with a specified current value toward the Comprising a voltage measuring unit for measuring a potential difference between the anode and the cathode of the detection target string, a determination unit failure of the bypass diode on the basis of the potential difference measured by the voltage measuring unit.

  Alternatively, the failure detection method according to another aspect of the present invention includes a plurality of solar cells connected in series that generate power using sunlight and at least one bypass diode connected in parallel to the plurality of solar cells. Failure detection for detecting a failure of a bypass diode in a solar cell system including a solar cell string including a plurality of solar cell modules connected in series and a load device connected to the solar cell string A switching step of switching a connection between a solar cell string and a load device to a disconnected state, and a solar cell string switched to a disconnected state by the switching step as a detection target string, from a negative electrode to a positive electrode of the detection target string A current supply step for supplying a current of a specified current value toward the A voltage measurement step for measuring a potential difference between the negative electrode and the positive electrode of the detection target string when supplying current by the current supply, and a determination step for determining a failure of the bypass diode based on the potential difference measured by the voltage measurement step. Prepare.

  According to such a failure detection system or failure detection method, a predetermined current value from the negative electrode to the positive electrode is applied to a solar cell string that includes at least one bypass diode and is switched in a disconnected state with respect to a load. A current is supplied, and a potential difference generated between the negative electrode and the positive electrode of the solar cell string at that time is measured, and a failure of the bypass diode is detected based on the potential difference. That is, if the bypass diode is normal, the potential difference is almost the same as the voltage drop value of the bypass diode. If the bypass diode is in open mode failure, the voltage drop value of the parasitic resistance of the solar cell string is generated. Becomes larger than the voltage drop value of the bypass diode. Therefore, according to the above-described failure detection system or failure detection method, the presence or absence of a failure of the bypass diode can be determined with high accuracy by detecting the difference in the magnitude of the potential difference. In addition, by measuring the potential difference in the constant current state, there is little risk of flowing a large current through the solar cell string, and there is no need to scan the IV characteristics as in the failure detection method using a capacitor. Thereby, the failure of the bypass diode can be detected easily and reliably while ensuring the safety at the time of inspection.

  In the failure detection system described above, the determination unit is measured in a state where a current having a first value that is larger than the short-circuit current value of the solar cell module is supplied as a specified current value to the detection target string. It is preferable to detect a failure of the bypass diode when the potential difference is larger than the first threshold value. In this way, the failure of the bypass diode can be detected with a simple process and circuit configuration by comparing the measured potential difference with the threshold value.

  Further, the determination unit is linear based on a change in potential difference measured in a state where the current values of the first and second values are supplied as the predetermined current values to the detection target string. It is also preferable that a failure of the bypass diode is detected based on whether or not, and at least one of the first and second current values is larger than the short-circuit current value of the solar cell module. By adopting such a configuration, it is determined whether the measured voltage difference changes linearly, thereby determining whether the voltage drop is caused by the parasitic resistance of the solar cell string or the bypass diode. Can do. As a result, it is possible to realize more reliable failure detection in consideration of characteristic changes due to aging of the bypass diode.

  Furthermore, the determination unit is configured such that a potential difference measured in a state where a current having a first value that is larger than a short-circuit current value of the solar cell module is supplied as a specified current value with respect to the detection target string. It is also preferable that the supply of current to the detection target string is stopped when the threshold value is larger than 1, or when the potential difference becomes equal to or greater than a second threshold value that is equal to or greater than the first threshold value. If such a determination unit is provided, it is possible to prevent a failure of the solar cell string caused by applying a high voltage to the solar cell string at the time of failure inspection. That is, if a constant current larger than the short-circuit current is passed through the solar cell string, a high voltage in the opposite direction to the voltage generated during power generation in the solar cell string may be generated, but the potential difference of the solar cell string is the first. Alternatively, the generation of such a high voltage can be prevented by stopping the supply of current when the second threshold value is reached.

  In addition, the determination unit is a detection target based on the comparison result between the short-circuit current value measured when the solar cell module is short-circuited or the open-circuit voltage measured when the solar cell module is opened and the specified value. It is preferable to determine whether or not the string is generating power, and to start determining whether or not the bypass diode has failed when it is determined that the detection target string is not generating power. With this configuration, the power generation state of the solar cell string can be determined by a simple determination method or a simple determination circuit.

  According to the present invention, it is possible to detect a failure of a bypass diode built in a solar cell module with high accuracy while ensuring safety.

It is a block diagram which shows the solar energy power generation system containing the failure detection system which concerns on 1st Embodiment of this invention. It is a figure which shows the detailed structure of the solar cell string contained in the solar energy power generation system of FIG. It is a figure which shows the equivalent circuit of the photovoltaic cell 140 of FIG. It is a graph which shows the current-voltage characteristic of the solar cell string of FIG. It is a graph which shows the current-voltage characteristic of the solar cell string of FIG. It is a graph which shows the current-voltage characteristic of the solar cell string of FIG. It is a block diagram which shows the solar energy power generation system containing the failure detection system which concerns on the modification of this invention.

  Hereinafter, embodiments of a failure detection device, a failure detection system, and a failure detection method according to the present invention will be described in detail with reference to the accompanying drawings. In the description of the drawings, the same elements are denoted by the same reference numerals, and redundant description is omitted.

  FIG. 1 is a configuration diagram of a solar power generation system according to an embodiment of the present invention, and FIG. 2 is a diagram illustrating a detailed configuration of a solar cell string included in the solar power generation system of FIG. A solar power generation system 1 shown in FIG. 1 is a power generation system that uses solar energy to generate power. For example, the solar power generation system 1 is installed in a high place such as a roof and has a grid connection type having an output voltage of 200 V or more. Has been. The solar power generation system 1 includes a solar cell array 100 and a power conditioner 110. Note that it is not necessary to limit to a grid-connected system, and an independent system independent (independent) from the power system may be used.

  The solar cell array 100 converts solar energy into electric energy and supplies it to the power conditioner 110 as a DC output. As shown in FIG. 2, the solar cell array 100 includes at least one solar cell string 130 in which a plurality of solar cell modules 120 are connected in series. Here, the solar cell array 100 is configured by connecting three solar cell strings 130 to each other in parallel. These solar cell strings 130 are connected to the power conditioner 110 via a switch group of the failure detection system 2 described later.

  The power conditioner 110 converts the direct current output supplied from the solar cell array 100 into an alternating current output, and supplies the alternating current output to an electric power system (for example, a commercial electric power system) connected to the load device at the subsequent stage. The power conditioner 110 has an operating voltage control function for controlling the operating voltage of the solar cell array 100 so that the maximum output of the solar cell array 100 can be obtained, and the system is safely stopped when an abnormality in the power system is detected. System protection function. The power conditioner 110 may be a transformer insulation type having an insulation transformer or a transformerless (non-insulation) type.

  The solar cell module 120 is configured in a panel shape, and includes a plurality (six in this case) of solar cells 140 connected in series with each other as shown in FIG. Moreover, the solar cell module 120 includes a bypass diode 150 connected in parallel to the plurality of solar cells 140 connected in series. That is, the anode terminal of the bypass diode 150 is connected to the negative electrode side of the solar cell module 120, and the cathode terminal of the bypass diode is connected to the positive electrode side of the solar cell module. Note that the solar cell module 120 may include a plurality of solar cell clusters including a plurality of solar cells 140 and bypass diodes 150 connected in parallel to them.

  The plurality of solar cells 140 generate power using sunlight, and are fixed to the aluminum frame in a state of being arranged in a matrix, and the light receiving surface side is covered with tempered glass. As the solar cell 140, for example, a crystalline solar cell having an output voltage of 0.5V is used.

  The bypass diode 150 is connected to the plurality of solar cells 140 in parallel. As the bypass diode 150, for example, a Schottky barrier diode is used in order to reduce the forward voltage and shorten the reverse recovery time. The bypass diode 150 is provided such that a current flows when a reverse voltage is applied to the solar cell module 120, and its forward direction is the forward direction of the equivalent parasitic diode of the solar cell 140 in the solar cell module 120. On the other hand, it is the opposite direction. Specifically, the cathode side of the bypass diode 150 is connected to the positive electrode side of the solar cell module 120 on the electric circuit connecting the solar cell modules 120 in series. The anode side of the bypass diode 150 is connected to the negative electrode side of the solar cell module 120 on the electric circuit.

  FIG. 3 shows an equivalent circuit diagram of the solar battery cell 140. As shown in the figure, the solar cell 140 can be considered equivalent to a parallel circuit of a current source 141, a parasitic diode 142, and a shunt resistor 143. That is, the solar cell 140 has a current source 141 that generates a current corresponding to the solar radiation intensity from the negative electrode to the positive electrode inside the cell 140, and a direction from the positive electrode to the negative electrode inside the cell 140 as a forward direction. This is equivalent to a parasitic diode 142 and a shunt resistor 143 having a resistance value of several hundred to 1 kΩ (ideally infinite Ω). Further, when a current equal to or greater than the current generated by the current source 141 is generated in the solar cell 140 from the negative electrode to the positive electrode, the current flows through the shunt resistor 143.

  Returning to FIG. 1, the configuration of the failure detection system 2 included in the solar power generation system 1 will be described. The failure detection system 2 is for detecting a failure of the bypass diode 150 incorporated in the solar cell string 130 for the solar cell string 130 that is switched to a disconnected state with respect to a load device such as the power conditioner 110. It is a device group. Specifically, the failure detection system 2 includes switch groups (switching units) 3 and 4 and a failure detection device 5.

  The switch group 3 is provided to switch the connection between the three solar cell strings 130 and the power conditioner 110 to the disconnected state when the bypass diode is inspected, and has six switching elements 31A and 31B corresponding to the number of the solar cell strings 130. , 32A, 32B, 33A, 33B. The switching elements 31 </ b> A, 31 </ b> B, 32 </ b> A, 32 </ b> B, 33 </ b> A, 33 </ b> B are switches that control the electrical connection between the solar cell string 130 and the power conditioner 110. As the switching elements 31A, 31B, 32A, 32B, 33A, and 33B, any configuration can be used as long as it cuts off the current. An electromagnetic switch such as a semiconductor switch or a mechanical relay can be used. The switching elements 31A, 31B, 32A, 32B, 33A, and 33B are closed during normal operation (during power generation), and connect the solar cell string 130 and the power conditioner 110 to each other, while being open during bypass diode inspection. And let them be disconnected from each other.

  Specifically, the switching elements 31A, 32A, and 33A are provided on an electric circuit that connects between the positive electrode of each solar cell string 130 and one input terminal of the power conditioner 110, and the switching elements 31B, 32B, and 33B. Is provided on an electric circuit that connects between the negative electrode of each solar cell string 130 and the other input terminal of the power conditioner 110. In addition, although the switch group 3 is provided on both electric circuits connected to the positive electrode and the negative electrode of the solar cell string 130, it may be provided only on one of the electric circuits. For example, the switch group 3 may be composed of only the switching elements 31A, 32A, and 33A. Even in such a configuration, the solar cell string 130 and the power conditioner 110 can be disconnected from each other during the bypass diode inspection.

  The switch group 4 is provided to electrically connect the three solar cell strings 130 and the failure detection device 5 during the bypass diode inspection, and includes six switching elements 41A corresponding to the number of the solar cell strings 130. , 41B, 42A, 42B, 43A, 43B. The switching elements 41A, 41B, 42A, 42B, 43A, and 43B are switches that control the electrical connection between the solar cell string 130 and the failure detection device 5, and are the same semiconductor switches and electromagnetic switches as the switch group 3. Can be adopted. The switching elements 41A, 41B, 42A, 42B, 43A, and 43B are normally opened (during power generation), and the failure detection device 5 is electrically disconnected from the solar cell string 130 while bypass diode inspection is performed. Sometimes they are closed and they are connected to each other.

  Specifically, the switching elements 41A, 42A, 43A are provided on an electric circuit that connects between the positive electrode of each solar cell string 130 and one connection terminal of the failure detection device 5, and the switching elements 41B, 42B, 43B. Are provided on the electric circuit connecting between the negative electrode of each solar cell string 130 and the other connection terminal of the failure detection device 5. In addition, although the switch group 4 is provided on both the electric circuits connected to the positive electrode and the negative electrode of the solar cell string 130, it may be provided only on one of the electric circuits. For example, the switch group 4 may be configured only from the switching elements 41A, 42A, and 43A. Even with such a configuration, the solar cell string 130 and the failure detection device 5 can be disconnected from each other at normal times.

  A backflow prevention diode (not shown) that prevents a reverse current from flowing through the solar cell string 130 is provided between the solar cell string 130 and the power conditioner 110. (Both poles) are connected in series on the electric circuit. The backflow prevention diode may be configured to be located in the electric circuit to be measured by the failure detection device 5 or may be configured to be located outside the electric circuit to be measured. That is, regardless of the position of the switch group 3 or the position of the connection points 61 to 66 with the failure detection device 5, it is located anywhere on the electric circuit connecting the positive electrode (or negative electrode) of the solar cell string and the power conditioner 110. (However, it is necessary to be located closer to the solar cell string 130 than the parallel connection point with the other solar cell strings 130).

  The failure detection device 5 includes a current source circuit 51, a voltage measurement unit 52, and a control / determination unit 53. The current source circuit 51 is a circuit that generates a constant current having a specified current value. Both terminals of the current source circuit 51 pass through three switching elements 41A, 42A, 43A and switching elements 41B, 42B, 43B, respectively. The battery string 130 can be connected to the positive electrode and the negative electrode. Here, the current value of the current generated by the current source circuit 51 can be adjusted by control by the control / determination unit 53. With such a current source circuit 51, a current having a predetermined current value from the negative electrode to the positive electrode is supplied to any one of the three solar cell strings 130.

  The voltage measuring unit 52 is a circuit unit for measuring a potential difference between the negative electrode and the positive electrode of the solar cell string 130, and both terminals thereof are respectively switching elements 41A, 42A, 43A and switching elements 41B, 42B, It is possible to connect to the positive and negative electrodes of the three solar cell strings 130 via 43B. Here, the measurement timing of the potential difference by the voltage measurement unit 52 can be controlled by the control / determination unit 53, and a signal indicating the potential difference measured by the voltage measurement unit 52 can be acquired by the control / determination unit 53. Has been. Such a voltage measurement unit 52 measures the potential difference in any of the three solar cell strings 130.

  The control / determination unit 53 performs control so that the open / close state of the switch groups 3 and 4 is switched during a failure inspection of the bypass diode, and acquires a potential difference measured by the voltage measurement unit 52. Then, the control / determination unit 53 detects a failure of the bypass diode 150 incorporated in any of the solar cell strings 130 based on the acquired potential difference and outputs a detection result. Such a control / determination unit 53 may be configured by a circuit unit such as an analog circuit or a digital circuit, or may be configured by an information processing apparatus such as a microcomputer.

  Here, before describing the details of the function of the control / determination unit 53, current-voltage characteristics (hereinafter referred to as "IV characteristics") when the solar cell string 130 is normal and when the bypass diode is faulty will be described.

FIG. 4A is a graph showing the IV characteristic of the solar cell string 130 at night (at low solar radiation intensity), and FIG. 4B is one of the IV characteristics of FIG. 4A. It is a graph which shows a part in detail. As shown in the figure, when both ends of the solar cell string 130 are short-circuited (V = 0), a short-circuit current _ISC is generated according to the intensity of light received by the solar cell string. Compared to the inside, it is usually extremely small, 1/1000 or less.

4A and 4B, L1 indicates the IV characteristic of the solar cell string 130 when it is normal, and L2 indicates the IV characteristic of the solar cell string 130 when the bypass diode is faulty. In these characteristics, when the potential of the positive electrode of the solar cell string 130 is higher than the potential of the negative electrode, a positive voltage (V> 0) is indicated, and the current from the negative electrode to the positive electrode is positive in the solar cell string 130. Current (I> 0) is shown. Since the solar cell string 130 includes a plurality of bypass diodes 150 in a forward direction from the negative electrode inside to the positive electrode, when a positive current (I> 0) is generated at night at normal time, As a result, almost no current flows through the shunt resistor 143 (FIG. 3) of the solar cell 140, and most of the current flows in the forward direction through the bypass diode 150, so that the voltage V across the solar cell string 130 is in the solar cell string 130. the total forward voltage of the bypass diode (V _f) contained in the ([sigma] v _f).

  On the other hand, when an open mode failure (failure in a state of not energizing) occurs in any of the bypass diodes 150 included in the solar cell string 130 and a positive current (I> 0) is generated at night, Almost no current flows through the failed bypass diode 150, and the current flows into the shunt resistor 143 of the solar cell 140 connected in parallel to the bypass diode 150. Therefore, the voltage V across the solar cell string 130 increases in current. Increases almost linearly.

The present invention utilizes the above principle, and determines whether the bypass diode is normal or has an open failure by measuring the voltage when a positive current (I> 0) flows at night. It is. That is, if the bypass diode is normal, the relationship between the voltage (V <0) when a positive current (I> 0) flows at night and the total value (ΣV _f ) of the forward voltage of the bypass diode is | V | = (ΣV _f ) On the other hand, if the bypass diode has an open mode failure, | V |> (ΣV _f ) Therefore, it is possible to determine whether or not the bypass diode has failed.

Here, as the threshold V _TH0 determination, even with total forward voltage of the bypass diode ([sigma] v _f), it is possible to determine the presence or absence of a fault, Ya slight fluctuations in this case measurements Due to the change in _Vf due to the temperature change of the bypass diode, there is a possibility that it may be erroneously detected that an open failure has occurred even though the bypass diode actually functions normally. Therefore, the threshold V _TH0 of determination, the sum of the forward voltage of the bypass diode is preferably a value larger than ([sigma] v _f). Conversely, when the bypass diode has an open failure, the absolute value of the voltage (V <0) depends on the product of the shunt resistance and the current value of the solar battery cell, and the total value of the forward voltage of the bypass diode (ΣV _f ) to become sufficiently larger than even the threshold V _TH0 determination as a sum value (a value greater than [sigma] v _f) of the forward voltage of the bypass diode, the risk of missing the open failure is small.

  The control / determination unit 53 determines a failure of the bypass diode 150 included in the solar cell string 130 using the IV characteristics of the solar cell string described above. Specifically, the control / determination unit 53 controls the switch group 3 so that the gap between any one of the solar cell strings 130 to be inspected (hereinafter also referred to as detection target strings) and the power conditioner 110. At the same time as setting the disconnected state, the switch group 4 is controlled to connect the detection target string 130 to the current source circuit 51 and the voltage measurement unit 52 of the failure detection device 5. For example, the control / determination unit 53 controls the pair of switching elements 31A and 31B, the pair of switching elements 32A and 32B, or the pair of switching elements 33A and 33B to be in an open state, and correspondingly The pair of switching elements 41A and 41B, the pair of switching elements 42A and 42B, or the pair of switching elements 43A and 43B is controlled to be closed.

In this state, the control / determination unit 53 controls the current source circuit 51 to have a current value I ₁ larger than the average short-circuit current value I _SC at night from the negative electrode to the positive electrode of the detection target string 130. Is generated. Further, the control / determination unit 53 determines whether or not the potential difference of the detection target string 130 measured by the voltage measurement unit 52 is larger than a predetermined threshold value V _TH0, and detects when the potential difference is larger than the threshold value V _TH0. A failure of any bypass diode 150 included in the target string 130 is detected. With such a function of the control / determination unit 53, it is possible to determine which of the characteristics L1 and L2 shown in FIG. 4 the IV characteristic of the detection target string 130 is, and the IV characteristic is the characteristic. A failure of the bypass diode 150 can be detected when it is determined as L2. That is, the potential difference measured by the voltage measuring unit 52 corresponds to the magnitude of the voltage V with respect to the current I = I ₁ on the characteristics L1 and L2, and therefore the potential difference is compared with the threshold value V _TH0. It is possible to determine whether the IV characteristics of the string 130 are in the characteristics L1 and L2.

Further, the control / determination unit 53 determines that the potential difference of the detection target string 130 measured by the voltage measurement unit 52 when the current of the current value I ₁ is supplied to the detection target string 130 is the threshold value V _TH0 or the predetermined value. When the threshold value V _TH1 (> threshold value V _TH0 ) is exceeded, the current source circuit 51 controls to stop the supply of current to the detection target string 130. At this time, the control / determination unit 53 starts monitoring the potential difference of the detection target string 130 at the timing when the open / close state of the switch groups 3 and 4 is switched for the failure inspection of the bypass diode, and according to the monitoring result Thus, it is continuously determined whether or not to stop the current supply to the detection target string 130. The voltage threshold V _TH1 for stopping the supply of current is obtained by adding the avalanche breakdown voltage of the solar battery cell to the determination threshold value V _TH0 for determining whether or not there is a failure so that the solar battery cell in the solar battery string is not damaged by the overvoltage. It is preferable to set it to be equal to or less than the above value.

  Next, the failure inspection procedure for the bypass diode 150 targeting the above-described photovoltaic power generation system 1 will be described, and the failure detection method according to the present embodiment will be described in detail.

First, the control / determination unit 53 of the failure detection device 5 determines whether or not a predetermined time has arrived by using a built-in timing function, and checks for a failure of the bypass diode at the timing when the arrival of the predetermined time is detected. Processing begins. For example, since the very small the I-V characteristic short-circuit current value I _SC of the solar cell string 130 at the timing of arrival of night time is detected is stable, bypassed by the fault test process is started at this timing False detection of a diode failure is prevented.

  Moreover, when detecting at night, since it can detect in a small electric current value, it becomes possible to detect safely.

  Next, the switch groups 3 and 4 are controlled by the control / determination unit 53 to set the disconnection state between any one of the detection target strings 130 and the power conditioner 110, and at the same time, the detection target string 130. Are connected to the failure detection device 5 (first switching step). Here, when set to the disconnected state, both poles of the detection target string 130 may be cut, or only one side of the detection target string 130 may be cut.

Thereafter, the detection target string 130 from the current source circuit 51 of the failure detection device 5, a current of a current value I ₁ is supplied toward the negative electrode to the positive electrode (current supply step). At this timing, the voltage measurement unit 52 measures the potential difference between the negative electrode and the positive electrode of the detection target string 130 and passes the measured value to the control / determination unit 53 (voltage measurement step). On the other hand, the control / determination unit 53 determines whether or not the measured value of the potential difference is larger than the specified threshold value V _{TH0, and} any bypass diode included in the detection target string 130 based on the determination result. 150 failures are detected (determination step). Then, the control / determination unit 53 outputs the detection result to an output device such as a display or an LED (output step). Finally, when a failure of the bypass diode is not detected (when the bypass diode is determined to be normal), the control / determination unit 53 controls the switch groups 3 and 4 to detect the detection target string 130 and the failure detection. At the same time as the connection with the device 5 is released, the connection between the detection target string 130 and the power conditioner 110 is set to the connected state (second switching step).

According to the failure detection system 2 described above and the failure detection method of the bypass diode using the failure detection system 2, the prescribed current value I from the negative electrode to the positive electrode is applied to the solar cell string 130 in the disconnected state with respect to the load device. ₁ is supplied, a potential difference generated between the negative electrode and the positive electrode of the solar cell string 130 is measured at that time, and a failure of the bypass diode 150 is detected based on the potential difference. That is, if the bypass diode 150 is normal, the potential difference is almost the same as the voltage drop value of the bypass diode 150, and if the bypass diode 150 is in an open mode failure, the parasitic resistance (shunt resistor 143) of the solar cell 140 is reduced. Since a voltage drop value is generated, the potential difference becomes larger than the voltage drop value of the bypass diode 150. Therefore, according to the failure detection method using the failure detection system 2 described above, it is possible to reliably determine whether or not the bypass diode 150 has failed by detecting the difference in the magnitude of the potential difference. In addition, by measuring the potential difference in the constant current state, there is little possibility of a large current flowing through the solar cell string, and there is no need to scan the IV characteristics as in the conventional failure detection method using a capacitor. Thereby, the failure of the bypass diode 150 can be detected easily and reliably while ensuring the safety at the time of inspection.

In the failure detection system 2 described above, a failure of the bypass diode 150 is detected when the potential difference measured with respect to the solar cell string 130 is larger than the threshold value V _TH0, so that the failure of the bypass diode 150 is detected with simple processing and circuit configuration. Can be detected. In addition, since the current value I ₁ supplied to the solar cell string 130 at the time of inspection is larger than the average short-circuit current value I _SC of the solar cell string 130 at night, bypass is performed regardless of the power generation state of the solar cell string 130. The failure of the diode 150 can be detected with high accuracy.

In addition, since the supply of current to the solar cell string 130 is stopped when the potential difference measured with respect to the solar cell string 130 becomes equal to or greater than the threshold value _VTH1 , applying a high voltage to the solar cell string 130 at the time of failure inspection The failure of the solar cell string 130 due to can be prevented. That is, if a constant current larger than the short-circuit current is passed through the solar cell string 130, a high voltage in the opposite direction to the voltage generated during power generation in the solar cell string 130 may be generated. The generation of such a high voltage can be prevented by stopping the supply of current when becomes too large.

  In addition, this invention is not limited to embodiment mentioned above. For example, the control / determination unit 53 supplies currents of two or more kinds of current values to the detection target string 130, and the detection target is based on the potential difference measured by the voltage measurement unit 52 for each current value. By determining whether the IV characteristic of the string 130 is linear, a failure of the bypass diode may be detected.

Specifically, in order to determine the IV characteristics L1 and L2 of the detection target string 130 as illustrated in FIG. 5, the control / determination unit 53 determines the current value of the current supplied to the detection target string 130 as I1 and I2. , I3 are controlled so as to be continuously changed, and the potential criteria V1, V2, V3 corresponding to the respective current values I1, I2, I3 are referred to and the following judgment criteria are used. Determine whether there is a failure in the bypass diode. First, the control / determination unit 53 uses the following formula based on the potential differences V1 and V2 measured with respect to the current values I1 and I2.
Vr = V1 + {(V2-V1) / (I2-I1)} * (I3-I1)
Is used to calculate the voltage value Vr. Then, the control / determination unit 53 determines that the bypass diode is normal, assuming that the IV characteristic of the detection target string 130 is non-linear if the measured potential difference V3 is smaller than the specified value compared to the voltage value Vr. On the other hand, if the absolute value | V3−Vr | of the difference between the measured potential difference V3 and the voltage value Vr is less than the specified value, the control / determination unit 53 determines that the IV characteristic of the detection target string 130 is linear. The bypass diode is determined to be abnormal.

  As another determination method, the following failure determination method may be employed. That is, in order to determine the IV characteristics L1 and L2 of the detection target string 130 as illustrated in FIG. 6, the control / determination unit 53 applies a current in the forward direction (direction from the negative electrode to the positive electrode) to the detection target string 130. The potential difference V4 measured when the value I is supplied is acquired, and the potential difference V5 measured when the current value I is supplied to the detection target string 130 in the reverse direction (direction from the positive electrode to the negative electrode). The control / determination unit 53 also acquires a voltage (open voltage) V0 (> 0) generated in the detection target string 130 when the supplied current value is zero. Then, the control / determination unit 53 refers to the acquired potential differences V0, V4, and V5, and determines that the bypass diode is normal if the value of V4 + V0 is smaller than a predetermined value compared to the value of V5-V0. On the other hand, if the difference between the value of V5−V0 and the value of V4 + V0 is less than the specified value, the control / determination unit 53 determines that the IV characteristic of the detection target string 130 is linear and determines that the bypass diode is abnormal. .

  As shown in FIG. 6, when the voltage V5 at the time of reverse current is measured and failure detection of the bypass diode in the detection target string 130 is performed, it is necessary to exclude the backflow prevention diode from the electric path of the detection target string 130. . That is, in this case, the individual backflow prevention diodes are positioned closer to the power conditioner 110 than the connection points 61 to 66 with the failure detection device 5 in the electric circuit connecting the individual solar cell strings 130 and the power conditioner 110. It is necessary to let

The control / determination unit 53 may determine whether or not the detection target string 130 is actually generating power when determining the start timing of the failure inspection process for the bypass diode. FIG. 7 shows a configuration of a failure detection system 202 according to a modification of the present invention in this case. As shown in the figure, the failure detection device 205 of the failure detection system 202 further includes a current measurement unit 551 and a switch 552 for measuring a short-circuit current value when the detection target string 130 is short-circuited. . The current measurement unit 54 is configured to be connectable to the negative electrode and the positive electrode of the detection target string 130 via the switch group 4. The switch 552 is a switch for short-circuiting the detection target string 130 including the current measuring unit 551, and is open except when the short-circuit current is measured. The control / determination unit 253 closes the switch 552 immediately after the first switching step, acquires the short-circuit current value measured by the current measurement unit 551, and compares the short-circuit current value with a specified value. To determine whether or not the detection target string is generating power, and when it is not generating power, the failure inspection process of the bypass diode is started. For example, the control / determination unit 253 determines that the detection target string 130 is not generating power when the measured short-circuit current value is smaller than a specified value. Alternatively, the control / judging unit 253, the detection object string 130 based on the constant current value I ₁ ratio measured short-circuit current value may be determined whether or not during power generation. For example, if I ₁ / I _SC ≧ α (α: integer), it may be determined that the power is not generated (at night).

  Furthermore, as another embodiment, only the failure detection device 5 in FIG. 1 may be prepared as an independent portable device and connected to a solar cell string, a solar cell module, or a solar cell cluster for detection.

  In the above embodiment, the method for performing detection at night has been described, but by passing a current larger than the short-circuit current of the solar cell, the voltage detection threshold value is the same as that for performing detection at night, while the daytime is used. Detection can also be performed.

  DESCRIPTION OF SYMBOLS 1 ... Solar power generation system (solar cell system), 2,202 ... Failure detection system, 3 ... Switch group (switching part), 5,205 ... Failure detection apparatus, 51 ... Current source circuit, 52 ... Voltage measurement part, 53 , 253 ... Control / determination unit, 61-66 ... Connection point, 100 ... Solar cell array, 110 ... Power conditioner (load device), 120 ... Solar cell module, 140 ... Solar cell, 150 ... Bypass diode, 551 ... Current measuring unit, 552... Switch.

Claims (12)

A solar cell that generates power using sunlight and at least one bypass diode connected in parallel to the solar cell, and targeting at least one solar cell module in a disconnected state with respect to a load, A failure detection device for detecting a failure of the bypass diode,
A current source for supplying a current of a predetermined current value from the negative electrode to the positive electrode of the solar cell module;
A voltage measuring unit that measures a potential difference between a negative electrode and a positive electrode of the solar cell module when a current is supplied by the current source;
A determination unit that determines a failure of the bypass diode based on the potential difference measured by the voltage measurement unit;
A failure detection apparatus comprising: The determination unit is configured such that the potential difference measured in a state where a current having a first value that is larger than a short-circuit current value of the solar cell module is supplied as the specified current value to the solar cell module. Detecting a failure of the bypass diode when greater than a first threshold;
The failure detection device according to claim 1. The determination unit is configured such that the change is linear based on the change in the potential difference measured in a state where the first and second current values are supplied as the prescribed current values to the solar cell module. Detecting a failure of the bypass diode based on whether or not
At least one of the current values of the first and second values is greater than a short circuit current value of the solar cell module;
The failure detection apparatus according to claim 1. The determination unit is configured such that the potential difference measured in a state where a current having a first value that is larger than a short-circuit current value of the solar cell module is supplied as the specified current value to the solar cell module. , When larger than the first threshold, or when the potential difference becomes equal to or greater than a second threshold that is equal to or greater than the first threshold, the supply of current to the solar cell module is stopped.
The failure detection apparatus according to claim 1. The determination unit is based on a comparison result between a short-circuit current value measured when the solar cell module is short-circuited, or an open-circuit voltage measured when the solar cell module is opened, and a specified value. It is determined whether the solar cell module is generating power, and when it is determined that the solar cell module is not generating power, the determination of the failure of the bypass diode is started.
The failure detection device according to any one of claims 1 to 4, wherein A plurality of solar cell modules including a plurality of solar cells connected in series that generate power using sunlight and at least one bypass diode connected in parallel to the plurality of solar cells are connected in series. A failure detection system for detecting a failure of the bypass diode for a solar cell system comprising a solar cell string and a load device connected to the solar cell string,
A switching unit that switches the connection between the solar cell string and the load device to a disconnected state;
A current source for supplying a current of a predetermined current value from the negative electrode of the detection target string to the positive electrode, using the solar cell string switched to the disconnected state by the switching unit as a detection target string;
A voltage measuring unit that measures a potential difference between a negative electrode and a positive electrode of the detection target string when a current is supplied by the current source;
A determination unit that determines a failure of the bypass diode based on the potential difference measured by the voltage measurement unit;
A failure detection system comprising: The determination unit is configured such that the potential difference measured in a state where a current having a first value that is larger than a short-circuit current value of the solar cell module is supplied as the specified current value to the detection target string. Detecting a failure of the bypass diode when greater than a first threshold;
The failure detection system according to claim 6. The determination unit is configured such that the change is linear based on a change in the potential difference measured in a state where the first and second current values are supplied as the specified current value to the detection target string. Detecting a failure of the bypass diode based on whether or not
At least one of the current values of the first and second values is greater than a short circuit current value of the solar cell module;
The failure detection system according to claim 6. The determination unit is configured such that the potential difference measured in a state where a current having a first value that is larger than a short-circuit current value of the solar cell module is supplied as the specified current value to the detection target string. Stopping the supply of current to the detection target string when the threshold value is larger than the first threshold value or when the potential difference becomes equal to or larger than a second threshold value equal to or larger than the first threshold value;
The failure detection system according to claim 6. The determination unit is based on a comparison result between a short-circuit current value measured when the solar cell module is short-circuited, or an open-circuit voltage measured when the solar cell module is opened, and a specified value. It is determined whether or not the detection target string is generating power, and when it is determined that the detection target string is not generating power, the determination of the failure of the bypass diode is started.
The failure detection system according to any one of claims 6 to 9, wherein A solar cell that generates power using sunlight and at least one bypass diode connected in parallel to the solar cell, and targeting at least one solar cell module in a disconnected state with respect to a load, A failure detection method for detecting a failure of the bypass diode,
A current supply step of supplying a current of a predetermined current value from the negative electrode of the solar cell module toward the positive electrode;
A voltage measurement step of measuring a potential difference between the negative electrode and the positive electrode of the solar cell module when supplying current by the current supply step;
A determination step of determining a failure of the bypass diode based on the potential difference measured by the voltage measurement step;
A failure detection method comprising: A plurality of solar cell modules including a plurality of solar cells connected in series that generate power using sunlight and at least one bypass diode connected in parallel to the plurality of solar cells are connected in series. A failure detection method for detecting a failure of the bypass diode targeting a solar cell system comprising a solar cell string and a load device connected to the solar cell string,
A switching step of switching the connection between the solar cell string and the load device to a disconnected state;
A current supply step of supplying a current of a predetermined current value from the negative electrode of the detection target string to the positive electrode, using the solar cell string switched to the disconnected state by the switching step as a detection target string;
A voltage measurement step of measuring a potential difference between a negative electrode and a positive electrode of the detection target string at the time of supplying a current by the current supply step;
A determination step of determining a failure of the bypass diode based on the potential difference measured by the voltage measurement step;
A failure detection method comprising:

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